A serigraphy method for producing a soulder bump on the front surface of a substrate includes: forming a film on the front surface, forming an opening in the film, filling the opening with a souldering material, and removing the film. Forming a film on the front surface is preceded by the formation of an intermediate layer between the film and the front surface, the intermediate layer being adapted to exhibit a force of adherence at one and/or the other interface formed with the first front surface and the film lower than the force of adherence that can be formed between the film and the first front surface.

A fiber-type electronic device comprising a pattern for electronic devices stacked on a fiber filament substrate is provided. It is possible to manufacture an electronic device directly on a fiber filament substrate by applying the pattern for electronic devices. Thus, it can be widely used for wearable devices and the like. The pattern for electronic devices is manufactured by a method for forming a pattern for electronic devices comprising an exposure process using a maskless exposure apparatus. Thus, it is possible to manufacture a pattern for electronic devices on a fiber filament substrate through a continuous process and thus to increase the process efficiency.

The present invention relates to a method for connecting an electrical contact to a nanomaterial carried by a substrate. At least one layer of soluble lithography resist is provided on the nanomaterial. An opening in the at least one layer of resist exposes a surface portion of the nanomaterial. At least a portion of the exposed surface portion of the nanomaterial is removed to thereby expose the underlying substrate and an edge of the nanomaterial. A metal is deposited on at least the edge of the nanomaterial and the exposed substrate such that the metal forms an electrical contact with the nanomaterial. Removing at least a portion of the soluble lithography resist from the nanomaterial such that at least a portion of the two-dimensional material is exposed.

A technique relates to a semiconductor device. An emitter electrode and a collector electrode are formed in a dielectric layer such that a nanogap separates the emitter electrode and the collector electrode, a portion of the emitter electrode including layers. A channel is formed in the dielectric layer so as to traverse the nanogap. A top layer is formed over the channel so as to cover the channel and the nanogap without filling in the channel and the nanogap, thereby forming a vacuum channel transistor structure.

A process for making an interconnect of a group III-V semiconductor device includes the steps of applying a positive photoresist layer and an image-reversible photoresist layer, subjecting the image-reversible photoresist and positive photoresist layers to patternwise exposure, subjecting the image-reversible photoresist layer to image reversal bake, subjecting the image-reversible photoresist and positive photoresist layers to flood exposure, subjecting the image-reversible photoresist and positive photoresist layers to development, depositing a diffusion barrier layer, depositing a copper layer, and removing the image-reversible photoresist and positive photoresist layers.

A metallic etching process includes applying an anti-reflection coating over a metallic superstrate, applying a dry film photoresist over the anti-reflection coating, removing exposed portions of the dry film photoresist exposing a portion of the anti-reflection coating, etching the exposed portions of the anti-reflection coating exposing portions of the metal superstrate, etching portions of the metallic superstrate not covered by the dry film photoresist, and removing the dry film photoresist and the anti-reflection coating leaving portions of the metallic superstrate. An indium bump liftoff process includes applying a positive photoresist, forming a liftoff mask by applying a dry film photoresist over the positive photoresist, removing exposed portions of the liftoff mask to expose a portion of a substrate, depositing an indium film over the exposed portion of the substrate and remaining portions of the liftoff mask, and removing remaining portions of the liftoff mask.

A support substrate including a plurality of channels on a front side is provided. A cover layer is formed by anisotropically depositing a sacrificial cover material over the plurality of channels. Cavities laterally extend within the plurality of channels underneath a horizontally extending portion of the cover layer. An encapsulation layer is conformally deposited. First semiconductor devices, first metal interconnect structures, and first bonding pads are formed over a top surface of the encapsulation layer. A device substrate with second bonding pads is provided. The second bonding pads are bonded with the first bonding pads to form a bonded assembly. Peripheral portions of the encapsulation layer are removes and peripheral portions of the cover layer are physically exposed. The cover layer is removed employing an isotropic etch process by propagating an isotropic etchant through the cavities to separate the support substrate from the bonded assembly.

A method for manufacturing a semiconductor device includes steps of forming a first photoresist film on a semiconductor substrate, and forming a second photoresist film having a higher acidity than the first photoresist film on the first photoresist film, forming an opening for exposing a surface of the semiconductor substrate by patterning the first photoresist film and the second photoresist film, applying a shrink material to an upper surface of the second photoresist film and an inside of the opening, and reacting the shrink material and the second photoresist film in the inside of the opening by heat-treating the first photoresist film, the second photoresist film and the shrink material, and removing an unreacted shrink material that do not react with the second photoresist film from the upper surface of the second photoresist film and the inside of the opening.

In a thin film electrode separation method using thermal expansion coefficient, a first solution is coated on a substrate. The first solution coated on the substrate is hardened. The substrate is left in a predetermined time, to form a first thin film having a first thermal expansion coefficient on the substrate. A photoresist is coated on the substrate having the thin film formed thereon. The photoresist coated on the substrate is hardened, to form a photoresist film having a second thermal expansion coefficient. A metal and a passivation layer are formed on the photoresist film. The photoresist film is detached from the first thin film, using difference of a thermal expansion coefficient between the photoresist film and the first thin film.

A semiconductor substrate (1) has a front surface and a rear surface facing each other. A gate wiring (2) and first and second front surface electrodes (3,4) are provided on the front surface of the semiconductor substrate (1). The first and second front surface electrodes (3,4) are separated from each other by the gate wiring (2). An insulating film (7) covers the gate wiring (2). An electrode layer (8) is provided on the insulating film (7) and the first and second front surface electrodes (3,4) across the gate wiring (2). A rear surface electrode (9) is provided on the rear surface of the semiconductor substrate (1). A first plated electrode (10) is provided on the electrode layer (8). A second plated electrode (11) is provided on the rear surface electrode (9).